Abstract: Disclosed are systems and methods for long distance transmission of offshore generated power. A turbine is located offshore. The turbine can be mechanically coupled to a generator. A guided surface waveguide probe is electrically coupled to the generator and configured to launch a guided surface wave on a terrestrial medium.

Abstract: Disclosed are various embodiments for transmitting energy conveyed in the form of a guided surface-waveguide mode along a lossy conducting medium such as, e.g., the surface of a terrestrial medium by exciting a polyphase waveguide probe. A probe control system can be used to adjust the polyphase waveguide probe based at least in part upon characteristics of the lossy conducting medium.

Abstract: Disclosed are various systems and methods for remote surface sensing using guided surface wave modes on lossy media. One system, among others, includes a guided surface waveguide probe configured to launch a guided surface wave along a surface of a lossy conducting medium, and a receiver configured to receive backscatter reflected by a remotely located object illuminated by the guided surface wave. One method, among others, includes launching a guided surface wave along a surface of a lossy conducting medium by exciting a charge terminal of a guided surface waveguide probe, and receiving backscatter reflected by a remotely located object illuminated by the guided surface wave.

Abstract: Disclosed are various embodiments of an electromagnetic hybrid phased array system. One such embodiment includes a guided surface waveguide probe, and a contrawound toroidal helix antenna collocated with the guided surface waveguide probe in which the contrawound toroidal helix comprises ring elements spaced from each other and wrapped around the guided surface waveguide probe. The system further includes a signal source applied to at least the guided surface waveguide probe, such that the guided surface waveguide probe and the contrawound toroidal helix contribute individual vertical electric fields to form a radiation pattern based on the phase and amplitude characteristics of the individual vertical electric fields.

Abstract: Disclosed are various embodiments for fixing a navigational position using guided surface waves launched from guided surface wave waveguide probes at various ground stations. A navigation unit may fix its position by determining the travel time of guided surface waves from the ground stations to the navigation unit. In another embodiment, the navigation unit may also fix its position by determining the change in intensity of the guided surface waves after travelling from the ground stations to the navigation unit. In other embodiments, the navigation unit may also fix its position by determining the difference in phases of phase-locked guided surface waves as they travel from the ground stations to the navigation unit.

Abstract: Disclosed are various systems and methods directed to the launching of a guided surface wave embodying a modulated signal using a guided surface waveguide probe. A modulated signal is generated and coupled to a guided surface waveguide probe. A resulting guided surface wave is launched that decays exponentially as a function of distance.

Abstract: Disclosed is a system and method for disaster warning recovery including a power modulator. A location is determined for an area affected by an emergency event. An emergency message is generated that corresponds to the emergency event. The emergency message is transmitted by via a guided surface wave. The guided surface wave is launched by a guided surface waveguide probe. The power modulator is coupled to the guided surface waveguide probe.

Abstract: Disclosed are various embodiments for embedding data on a guided surface wave. A guided surface waveguide probe emits power as a guided surface wave received by a guided surface wave receive structure circuit. An aggregate electric load of the receiver circuit is modulated with reference to a data signal. A current at the guided surface waveguide probe is monitored. A data signal is recaptured at the guided surface waveguide probe.

Abstract: Disclosed is a support structure for a guided surface waveguide probe. In some embodiments, the support structure includes vertically oriented corner columns that define outer corners of the structure, vertically oriented intermediate columns that define portions of outer sides of the structure, each intermediate column being positioned between a pair of corner columns, framing members that extend between the corner columns and the intermediate columns, plates located at junctions between the framing members and the columns, and fasteners located at the junctions that secure the framing members and the plates to the corner columns and the intermediate columns, and that secure the framing members to the plates, wherein the corner columns, intermediate columns, framing members, plates, and fasteners are all made of a non-conductive material.

Abstract: Disclosed is a support structure for a guided surface waveguide probe. In some embodiments, the support structure includes vertically oriented corner columns that define outer corners of the structure, vertically oriented intermediate columns that define portions of outer sides of the structure, each intermediate column being positioned between a pair of corner columns, framing members that extend between the corner columns and the intermediate columns, plates located at junctions between the framing members and the columns, and fasteners located at the junctions that secure the framing members and the plates to the corner columns and the intermediate columns, and that secure the framing members to the plates, wherein the corner columns, intermediate columns, framing members, plates, and fasteners are all made of a non-conductive material.

Abstract: Disclosed are various embodiments for providing temperature measurements of a guided surface wave probe and/or a support structure. In one embodiment, among others, a system comprises a guided surface waveguide probe configured to launch a guided surface wave along a lossy conducting medium, where the guided surface waveguide probe generates heat while in operation. The support structure comprises non-conducting structural components that support the electrical components of the guided surface waveguide probe. The system also comprises a temperature sensor positioned on one of the non-conducting structural components.

Abstract: Disclosed is an exemplary guided surface waveguide probe configured to launch a guided surface wave along a surface of a lossy conducting medium. In one embodiment, the guided surface waveguide probe comprises a charge terminal elevated to a height above the lossy conducting medium; a support structure that supports the charge terminal; at least one section of internal coil that is supported within the support structure and is coupled to an excitation source; a conductive tube conductively coupled to the at least one section of internal coil at a bottom end, and a plurality of coupling conductors that extend radially away from a top of the conductive tube to a plurality of points located on an inner surface of the charge terminal.

Abstract: A guided surface waveguide probe structure is described. In one example, the guided surface waveguide probe structure includes a charge terminal elevated to a first height above a lossy conducting medium and a phasing coil elevated to a second height above the lossy conducting medium, wherein the first height is larger than the second height. The structure further includes a non-conductive support structure to support the phasing coil and the charge terminal. The non-conductive support structure includes a truss frame secured to and supported over a substructure, and the truss frame supports the phasing coil at the second height above the lossy conducting medium. The non-conductive support structure also includes a charge terminal truss extension supported by the truss frame, and the charge terminal truss extension supports the charge terminal at the first height above the lossy conducting medium.

Abstract: Disclosed is an exemplary guided surface waveguide probe. In one embodiment, the guided surface waveguide probe comprises a charge terminal elevated to a height above the lossy conducting medium; a support structure that supports the charge terminal; an internal coil that is supported within the support structure and is coupled to an excitation source; a conductive tube having a first end conductively coupled to the at least one section of internal coil, wherein a second end of the conductive tube extends vertically towards and is electrically coupled to the charge terminal; at least one sensor electrically coupled to the charge terminal or the internal coil, wherein the at least one sensor measures an operational parameter of the guided surface waveguide probe; and a non-conductive channel connected to the at least one sensor by which data associated with the operational parameter is communicated.

Abstract: Disclosed are embodiments for anchoring a guided surface waveguide probe. A guided surface waveguide probe can be suspended from a support structure manufactured from a nonconductive material, the support structure comprising a plurality of beams. A base bracket is configured to receive at least one of the plurality of beams and further comprising a hole. The base bracket rests upon a pad. An anchor bolt protrudes from the pad through the hole of the base bracket. Also, a fastener engages the anchor bolt to secure the base bracket to the pad.

Abstract: Disclosed are various embodiments for eliminating or minimizing atmospheric discharge within the internal phasing coil of the guided surface waveguide probe. A guided surface waveguide probe comprises a charge terminal elevated over a lossy conducting medium. The shape of the charge terminal is designed to minimize atmospheric discharge. A top portion of a coil being configured to provide a voltage to the charge terminal with a phase delay that matches a wave tilt angle associated with a complex Brewster angle of incidence associated with the lossy conducting medium is recessed within a hollow region of the charge terminal.

Abstract: Disclosed are various embodiments for transmitting and receiving energy conveyed in the form of a guided surface-waveguide mode along the surface of a lossy medium such as, e.g., a terrestrial medium excited by a guided surface waveguide probe.

Abstract: Disclosed are various embodiments for eliminating or minimizing atmospheric discharge within the guided surface waveguide probe. Atmospheric discharge can be minimized to a nominal amount according to one or more factors, such as, for example, the use of a corona hood, the effective diameter of the internal coil, the effective diameter of the tube, and the shape of the charge terminal.

Abstract: Disclosed is a support structure for a guided surface waveguide probe. In some embodiments, the support structure includes vertically oriented corner columns that define outer corners of the structure, vertically oriented intermediate columns that define portions of outer sides of the structure, each intermediate column being positioned between a pair of corner columns, framing members that extend between the corner columns and the intermediate columns, plates located at junctions between the framing members and the columns, and fasteners located at the junctions that secure the framing members and the plates to the corner columns and the intermediate columns, and that secure the framing members to the plates, wherein the corner columns, intermediate columns, framing members, plates, and fasteners are all made of a non-conductive material.

Abstract: Embodiments of a guided surface waveguide probe are disclosed. One embodiment, among others, has a guided surface waveguide probe including a charge terminal elevated over a lossy conducting medium by way of a support structure, and a substantially planar support platform situated under the support structure and co-planar with a roof of a substructure of the guided surface waveguide probe. The platform can include an aperture of sufficient size to enable a phasing coil to be moved vertically through the aperture for installation and removal of same. The support platform can be made from or include an insulating material part that is sufficiently insulating to prevent degradation of the support platform caused by the electric fields. A primary coil associated with the guided surface waveguide probe can magnetically couple with the phasing coil to excite the charge terminal to produce a guided surface wave on the lossy conducting medium.